Symposia of the Society for Experimental Biology最新文献

The Arabidopsis ETR1 gene codes for an ethylene hormone receptor that has striking sequence similarity with bacterial two-component regulators. This finding predicts that the ETR1 receptor transduces the ethylene signal through the phosphotransfer mechanisms established for a number of the bacterial regulators. To test this hypothesis, we have performed in vitro assays for ETR1 autokinase activity as well as for transfer of phosphate to the ETR1 receiver. So far, we have not detected either of these activities. Another question we are focusing on is the identity of protein substrates of the ETR1 receptor. Using the yeast two-hybrid system, we have obtained several clones to be subsequently characterized as potential interactors with ETR1.

Development can be considered to comprise the co-ordinated regulation of patterning at different levels: patterning of cells to form tissues, patterning of tissues to form organs, and patterning of organs to generate the characteristic architecture of the organism. These processes are expected, in turn, to be mediated by the precise spatial and temporal regulation of patterns of gene expression during development, which depend on appropriate signalling mechanisms. In order to investigate molecular events of morphogenesis in plants, we have utilized a system of promoter trap insertional mutagenesis in Arabidopsis, to generate both phenotypic mutants and gene fusions that represent markers useful in studying the regulation of patterning. A screen of transgenic seedlings containing a T-DNA promoter trap has led to the identification of mutants defective in seedling shape and embryonic development, and of GUS fusion genes that are expressed in spatially restricted patterns. Mutants have been crossed with marker lines expressing cell type-specific GUS activities, to investigate their cellular organization. For example, the POLARIS marker gene is expressed in the embryonic and seedling root tip. When crossed with hydra, which lacks an embryonic root, and with emb30, which lacks both embryonic and seedling roots, it is nevertheless expressed in the correct relative position, and we hypothesize that it represents a novel marker of root positional information, independent of root morphogenesis.

Located at a botanical department at an Agricultural University, our taxonomical and genetic research is mainly directed towards cultivated plants and their wild relatives. The investigations are usually under a common heading 'experimental taxonomy', and include basic systematics, cytogenetics, biodiversity, population dynamics, conservation and evolutionary questions correlating the wild species and the cultivated forms. Our point of initiation is the plants and questions/problems raised regarding these plants. Our way of approaching the problems is usually by applying different sets of data and testing them. Experimental taxonomy covers classical cytogenetics (chromosome counting and karyotyping) as well as molecular cytogenetic methods (RAPD, RFLP, in situ hybridization), and includes also chemical data on isoenzymes and anthocyanins. We have had good collaborations with other laboratories and found their expertise on the plants in question very helpful. The aim is always to unify various data on the same set of problems, in order to get a more complete understanding of the plants. At present the department is working on several, quite different plant genera, comprising herbs, aquatic plants, and trees. The methods vary, depending on the plants and the problems in question. Some of the current investigations concern the horticultural genera Lilium and Crocus, in which the main point of interest is the study of chromosome evolution using fluorescence in situ hybridization; preliminary investigations into the composition of anthocyanins in Crocus look very promising. In the tropical starch tuber crop Pachyrhizus (Fabaceae), molecular analyses of relationships between existing cultivars, landraces and wild material have been carried out. A genus which we, in cooperation with a number of other laboratories, have been working with for many years is Hordeum (Poaceae) with one cultivated species (barley) and 31 wild species. Here the main areas of investigation have been field studies and collecting, followed by a taxonomical treatment, hybridization experiments, cytogenetic analysis and isoenzyme studies. Within the field of forestry, we have used population genetics as a tool in the management of natural and domesticated populations and for conservation of genetic diversity. We have also ventured into the identification and use of DNA markers that are suited for genome mapping in Picea abies (Norway Spruce).

Recent studies have shown that grass genomes have very similar gene compositions and regions of conserved gene order, as exemplified by collinear genetic maps of DNA markers. We have begun the detailed study of sequence organization in large (100-500 kb) segments of the nuclear genomes of maize, sorghum and rice. Our results indicate collinearity of genes in the regions homoeologous to the maize adh1 and sh2-a1 genes. Comparable genes were found to be physically closer to each other in grasses with small genomes (rice and sorghum) than they are in maize. In several instances, we have found evidence of tandem and 'distantly tandem' duplications of segments containing maize and sorghum genes. These duplications complicate characterizations of microcollinearity and could also interfere with some map-based approaches to gene isolation.

DNA markers and genetic maps will be important tools for direct investigations of several facets of crop improvement and will provide vital links between plant breeding and basic plant biology. The markers and maps will become more important for increased crop production because plant genetics will be required to extend or replace extant management practices such as chemical fertilizers, pesticides, and irrigation (Lee, 1995). Despite the importance of the sorghum crop, comprehensive genetic characterization has been limited. Therefore, the primary goal of this research program was to develop basic genetic tools to facilitate research in the genetics and breeding of sorghum. The first phase of this project consisted of constructing a genetic map based on restriction fragment length polymorphisms (RFLPs). The ISU sorghum map was created through linkage analysis of 78 F2 plants of an intraspecific cross between inbred CK60 and accession P1229828 (Pereira et al., 1994). The map consists of 201 loci distributed among 10 linkage groups covering 1,299 cM. Comparison of sorghum and maize RFLP maps on the basis of common sets of DNA probes revealed a high degree of conservation as reflected by homology, copy number, and collinearity. Examples of conserved and rearranged locus orders were observed. The same sorghum population was used to map genetic factors (mutants and QTL) for several traits including vegetative and reproductive morphology, maturity, insect, and disease resistance. This presentation will emphasize analysis of genetic factors affecting plant height, an important character for sorghum adaptation in temperate latitudes for grain production. Four QTL for plant height were identified in a sample of 152 F2 plants (Pereira and Lee, 1995) whereas 6 QTL were detected among their F3 progeny. These observations and assessments of other traits at 4 QTL common to F2 plants and their F3 progeny indicate some of these regions correspond to loci (dw) previously identified on the basis of alleles with highly qualitative effects. Four of the six sorghum plant height QTL seem to be orthologous to plant height QTL in maize. Other possible instances of orthologous QTL included regions for maturity and tillering. These observations suggest that the conservation of the maize and sorghum genomes encompasses sequence homology, collinearity, and function. The genetic information and technology developed on the basis of DNA markers could be used in several facets of breeding, genetics, and other basic biological investigations. In addition, DNA markers have been used to survey large collections of elite sorghum germ plasm to determine the degree of genetic relationships and genetic diversity (Ahnert et al., 1996). RFLP data seem to portray genetic relationships more accurately than the methods based exclusively on the coancestry coefficient. This information provides the basis for more accurate perceptions of genetic relationships and diversity.

Molecular cytogenetics combines molecular information of DNA sequences with their chromosomal organization. Genomic in situ hybridization using total genomic DNA as a probe is proving particularly useful to paint chromosomes originating from different genomes in hybrids, alloploid species and alien plant breeding lines. Both the numbers and morphologies of alien chromosomes or chromosome segments can be detected at metaphase and interphase. The method also gives considerable information about species relationships and the distribution of common or diverse DNA sequences between closely related species. Painted chromosomes can be followed through all stages of the cell cycle of somatic and meiotic division, providing new information about chromosome behaviour and pairing at meiosis. In situ hybridization with defined probes enables the physical location of particular DNA sequences to be examined along chromosomes and the analysis of the long range organization of specific chromosome regions. The generation of an integrated genetical, physical and functional map will be useful for the understanding of the organization and structure of the cereal genome.

Many genes are similar in most plants and it is clear that the ordering of genes is highly conserved across wide taxonomic groupings. Repetitive DNA, consisting of sequence motifs between 2 and 10,000 base pairs long, repeated many hundreds or thousands of times in the genome, represents the majority of most plant genomes and defines some of the differences between species. Some sequences are highly conserved in many species, while other sequences show species or even chromosome specificity. Different types of sequences have markedly contrasting genomic distributions; even among tandem repeats, some are sub-terminal, some paracentromeric and others intercalary. The reasons for these different distributions are largely unknown, and mechanisms of homogenization, dispersion and amplifications are the subject of much speculation. Aspects of plant genome architecture-the organization of repetitive and single-copy DNA sequences along the chromosomes, and the positioning of those sequences within the nucleus at interphase-have important consequences for plant genetics. Models of large scale genome organization may be useful in learning the function of different components of the genome, in evolutionary studies and in plant breeding.

Three principal approaches have been used in our laboratory to analyze Triticeae genomes. (i) Synteny analysis: synteny among different Gramineae genomes was studied employing the elegant system of the Agropyron chromosome-induced deletion lines of wheat. Deletion mapping, predominantly of the homoeologous group 7 chromosomes, has led to the construction of a high density physical consensus map of wheat. The integration of wheat, barley and oat RFLP markers proves the colinearity between the wheat A-, B- and D-genomes, the H-genome of barley, and the E-genome of Agropyron. (ii) Light microscopic in situ techniques: the recent improvement of a drop technique for plant protoplasts was crucial for the sensitivity enhancement of fluorescence in situ hybridization (FISH), the efficient preparation of plant chromosomes for high resolution scanning electron microscopy, mapping of low-copy sequences, and comparative in situ hybridization. A tandemly amplified repetitive sequence element from microdissected barley chromosomes has enabled the karyotyping of Gramineae genomes in a single step. We have isolated and characterized members of this element family from other Triticeae species using PCR. The significant interspecific sequence differences were useful to identify single plant genomes, chromosomes and chromosome segments via post-hybridization washes under different stringency conditions. These sequences are also useful for simultaneous double or triple hybridization experiments in an attempt to localize new sequences on specific chromosomes or chromosome segments. The physical mapping of the Sec-1 locus has been refined on the satellite of chromosome 1R of rye, and the syntenic locus on barley chromosome 1H was identified. (iii) Physical mapping of rDNA sequences by high resolution electron microscopy: a method was developed for in situ hybridization and signal detection using high resolution field emission scanning electron microscopy and a backscattered electron detector. Colloidal gold particles were localized on chromosome structures resembling the 30 nm fibre. An rDNA probe was located in the secondary constriction and the highly compact adjacent regions of barley chromosomes.

Slash pine is native to the southeastern USA, but is commercially valuable world-wide as a timber-, fiber- and resin-producing species. Breeding objectives emphasize selection for fusiform rust disease resistance. Identification of markers linked to genetic factors conditioning specificity should expand our knowledge of disease development. Towards this end, random amplified polymorphic DNA (RAPD) markers were identified and mapped in a tree hypothesized to be homozygous dominant for resistance at one locus and homozygous recessive at another. Because the DNA prepared for analysis was from haploid maternally-inherited, megagametophyte tissue of seeds, RAPD markers were observed as either present or absent. The analysis revealed 13 linkage groups of three or more loci, ranging in size from 28 to 68 cM, and nine linked pairs. The 22 groups and pairs included 73 RAPD markers and covered a genetic map distance of approximately 782 cM. Genome size estimates, based on linkage data, range from 2,880 to 3,360 cM, and equal 6.0-6.9 x 10(6) bp/cM (physical size > 20,000 Mbp). Using a 30 cM map scale and including unlinked markers, ends of linkage groups, and linked pairs, the RAPD markers account for approximately 2,160 cM or 64-75% of the genome. Mapping 80 additional RAPD markers placed 131 loci total in 20 linkage groups of three or more loci, nearly doubling the coverage in the groups to a genetic map distance of approximately 1,347 cM. Two other slash pine trees also have been RAPD mapped. DNA-DNA in situ hybridization and cytochemical staining are being used to integrate the genetic recombinational maps. A karyotype and ideogram have been prepared for slash pine (2n = 2x = 24); metaphase chromosome preparations show 11 pairs of long metacentric chromosomes and one shorter pair of submetacentric chromosomes. Patterns of fluorescence in situ hybridization to genes for the large and small rRNA subunits and fluorochrome banding patterns using the GC-base-specific chromomycin A3 (CMA) and AT-base-specific 4',6-diamidino-2-phenylindole (DAPI) allowed all twelve pairs of chromosomes to be identified and a standard karyotype established. A family of sequences associated with (TTTAGGG)n related repeats has been identified in slash pine using a labeled synthetic oligonucleotide probe. Fluorescence in situ hybridization shows a weak signal at telomeres and significantly stronger intensity at non-telomeric sites. The most common non-telomeric location was in the pericentric regions of chromosomes; interstitial sites of hybridization were relatively common. Microsatellite DNAs, an abundant retrotransposon-like element, and total genomic in situ hybridization and species and chromosome specific DNAs are being evaluated for analyses of interspecific hybrids and chromosome evolution between related species. Interest in low and single copy sequences is increasing.

Insects and drought cause severe losses in the production of maize in many developing countries. Conventional breeding efforts to enhance the level of resistance to a number of insect pests and tolerance to drought have been successful, although only through large efforts of many breeders and over a large period of time. Continued improvements will only be possible through substantial investment of resources. Recently, success in identifying quantitative trait loci (QTL) in several plant species using various molecular marker systems offers alternative methods for accelerating conventional breeding programs. As the first step towards using molecular markers in CIMMYT's maize breeding program, restriction fragment length polymorphisms (RFLPs) have been used to understand the genetic basis of resistance to two corn borer species, southwestern corn borer and sugarcane borer, and to one major component of drought tolerance, anthesis-silking interval. A number of QTL with effects large enough to be regarded as significant in breeding were detected for each of these traits and many of them presented stable effects over environments. While variability in the number and location of QTL has been found when compared across populations, several loci were found to be quite consistent. Simple calculations can be made which estimate that the total genetic potential in maize for these traits is high. It is argued that to ultimately access and manipulate this potential, the use of linked molecular markers as indirect selectable markers is both feasible and necessary.